Fuel cell and fuel cell stack

ABSTRACT

A fuel cell including a pair of connectors ( 12, 13 ); a single cell ( 20 ) having an electrolyte layer ( 2 ) and electrode layers ( 14, 15 ); and current-collecting members ( 18, 19 ) disposed between the electrode layers and the connectors ( 12, 13 ), respectively. The current-collecting members ( 19 ) corresponding to at least the one electrode layer ( 15 ) has connector contact portions ( 19   a ) in contact with the connector ( 13 ), cell contact portions ( 19   b ) in contact with the electrode layer ( 15 ), connection portions ( 19   c ) connecting corresponding connector contact portions ( 19   a ) and cell contact portions ( 19   b ), and a spacer ( 58 ) disposed between the connector contact portions ( 19   a ) and cell contact portion ( 19   b ). An end of the spacer ( 58 ) located opposite the connection portions ( 19   c ) recedes from the ends of the cell contact portions ( 19   b ) located opposite the connection portions ( 19   c ) and from the ends of the connector contact portions ( 19   a ) located opposite the connection portions ( 19   c ).

CROSS-REFERENCE TO RELATED APPLICATION

This international application claims priority to Japanese Patent Application No. 2013-016489 filed with Japanese Patent Office on Jan. 31, 2013, and the entire contents of Japanese Patent Application No. 2013-016489 are incorporated herein by reference.

TECHNICAL FIELD

The present invention relates to a fuel cell which includes a single cell configured such that electrode layers are formed on the upper and lower surfaces, respectively, of an electrolyte layer and which generates electricity through supply of fuel gas to one electrode layer (hereinafter, called an anode layer) side and oxidizer gas to the other electrode layer (hereinafter, called a cathode layer) side, as well as to a fuel cell stack in which a plurality of the fuel cells are fixedly stacked.

BACKGROUND ART

Conventionally, as described in, for example, Patent Document 1, there is a fuel cell including a pair of interconnectors; a single cell located between the interconnectors and configured such that a cathode layer is formed on one surface of an electrolyte layer, and an anode layer is formed on the other surface; and current-collecting members disposed between the cathode layer and the interconnector and between the anode layer and the interconnector, respectively, to electrically connect the cathode layer and the interconnector, and the anode layer and the interconnector.

The current-collecting members of the fuel cell have a structure in which nail-like electrically conductive members are raised through cutting from a flat-plate-like current-collecting plate, and the flat surface of the current-collecting plate is joined to the interconnector, while tips of the electrically conductive members are brought in contact with a single cell, thereby establishing electrical connection.

PRIOR ART DOCUMENT Patent Document

-   Patent Document 1: Japanese Patent Application Laid-Open (kokai) No.     2009-266533

SUMMARY OF THE INVENTION Problem to be Solved by the Invention

In some cases, the conventional current-collecting member which is brought in contact with a single cell through elasticity of the electrically conductive members fails to have expected elastic force due to plastic deformation as a result of use over a long period of time, deterioration in strength of the electrically conductive members caused by high-temperature heat generated in the course of generating electricity, and influence of creep deformation on the electrically conductive members. In such a case, the electrically conductive members have failed to follow deformation of the single cell resulting from temperature cycles and fluctuations in fuel pressure and air pressure; as a result, contact has potentially become unreliable, potentially resulting in unreliable electrical connection between the cathode layer and the interconnector or between the anode layer and the interconnector.

Also, in the case of combined occurrence of the above-mentioned causes for deterioration in elastic force of the electrically conductive members, portions of the electrically conductive members expected to come into contact with the single cell may come into contact with the interconnector side; incidentally, the current-collecting member is formed of a material excellent in joining to the interconnector, since the current-collecting member is joined at its flat surface to the interconnector; thus, if, as mentioned above, the electrically conductive members come into contact with the interconnector side in a high-temperature environment in the course of generating electricity, the electrically conductive members may be joined to the interconnector side through sintering in some cases. In such a case, the electrically conductive members are integrated with the interconnector; accordingly, contact with the single cell becomes difficult; therefore, there has been a risk of unreliable electrical connection between the cathode layer and the interconnector or between the anode layer and the interconnector.

The present invention has been conceived in view of the foregoing, and an object of the invention is to provide a fuel cell and a fuel cell stack which can maintain good electrical connection even in use over a long period of time.

Means for Solving the Problem

In order to achieve the above-mentioned object, the present invention provides a fuel cell comprising:

a pair of interconnectors;

a single cell located between the interconnectors and having an electrolyte layer and electrode layers formed on upper and lower surfaces, respectively, of the electrolyte layer; and

current-collecting members disposed between the electrode layers and the interconnectors, respectively, and adapted to electrically connect the corresponding electrode layers and interconnectors;

the fuel cell being characterized in that

the current-collecting member corresponding to at least one of the electrode layers comprises a connector contact portion in contact with the interconnector, a cell contact portion in contact with the electrode layer of the single cell, a connection portion connecting the connector contact portion and the cell contact portion, and a spacer disposed between the connector contact portion and the cell contact portion; and

an end of the spacer located opposite the connection portion recedes from an end of the cell contact portion located opposite the connection portion and from an end of the connector contact portion located opposite the connection portion.

Also, the above fuel cell may be characterized in that the electrolyte layer is a plate-like one.

Also, the above-mentioned fuel cell may be characterized in that one of or both of the connector contact portion and the cell contact portion have an inwardly-warped warp end formed at a side opposite the connection portion.

Also, the fuel cell may be such that the warp end is engaged with an edge of the spacer.

In order to achieve the above-mentioned object, as described in a claim, the present invention provides a fuel cell comprising:

a pair of interconnectors;

a single cell located between the interconnectors and having a plate-like electrolyte layer and electrode layers formed on upper and lower surfaces, respectively, of the electrolyte layer; and

current-collecting members disposed between the electrode layers and the interconnectors, respectively, and adapted to electrically connect the corresponding electrode layers and interconnectors;

the fuel cell being characterized in that

the current-collecting member corresponding to at least one of the electrode layers comprises a connector contact portion in contact with the interconnector, a cell contact portion in contact with the electrode layer of the single cell, a connection portion connecting the connector contact portion and the cell contact portion, and a spacer disposed between the connector contact portion and the cell contact portion; and

an end of the spacer located opposite the connection portion recedes from an end of the cell contact portion located opposite the connection portion and from an end of the connector contact portion located opposite the connection portion.

As described in another claim, the present invention provides a fuel cell according to the aforementioned claim, wherein one of or both of the connector contact portion and the cell contact portion have a warp end formed at a side opposite the connection portion for engagement with an edge of the spacer.

As described in another claim, the present invention provides a fuel cell according to any one of the aforementioned claims, wherein the warp end is formed through shear deformation which occurs when at least one of the connector contact portion and the cell contact portion is stamped from a metal sheet.

As described in another claim, the present invention provides a fuel cell according to any one of the aforementioned claims, wherein, as viewed in plane, at least a portion of the current-collecting member opposite the current-collecting member corresponding to the one electrode layer is in contact with the other electrode layer in a region where the spacer is in contact with the cell contact portion and with the connector contact portion.

As described in another claim, the present invention provides a fuel cell according to any one of the aforementioned claims, wherein the entire region of the spacer as viewed in plane is contained, as viewed in plane, in a region of contact between the cell contact portion and the electrode layer.

As described in another claim, the present invention provides a fuel cell according to any one of the aforementioned claims, wherein the spacer is of at least one of mica, alumina felt, vermiculite, carbon fiber, silicon carbide fiber, and silica.

As described in another claim, the present invention provides a fuel cell according to any one of the aforementioned claims, further comprising a tightening member for unitarily tightening a stack of the interconnectors, the single cell, and the current-collecting members, wherein the tightening member and the spacer press the cell contact portion of the current-collecting member against the single cell and the connector contact portion of the current-collecting member against the interconnector.

As described in another claim, the present invention provides a fuel cell according to any one of the aforementioned claims, wherein the spacer is higher in thermal expansion coefficient in a tightening direction than the tightening member.

As described in another claim, the present invention provides a fuel cell according to any one of the aforementioned claims, wherein the current-collecting members are formed of a porous metal, a metal mesh, wire, or a punched metal.

As described in another claim, the present invention provides a fuel cell according to any one of the aforementioned claims, wherein the cell contact portion of the current-collecting member is joined to a surface of the electrode layer of the single cell.

As described in another claim, the present invention provides a fuel cell according to any one of the aforementioned claims, wherein the connector contact portion of the current-collecting member is joined to the interconnector.

As described in another claim, the present invention provides a fuel cell according to any one of the aforementioned claims, wherein the current-collecting member is disposed between the electrode layer corresponding to fuel gas and the interconnector and is formed of Ni or an Ni alloy.

As described in another claim, the present invention provides a fuel cell stack configured such that a plurality of the fuel cells according to any one of the aforementioned claims are stacked and fixed together by the tightening member.

Effects of the Invention

According to the fuel cell described in the aforementioned claim, since the spacer restrains deformation of the connector contact portion and the cell contact portion in a direction opposite contact, the connector contact portion and the cell contact portion are unlikely to undergo plastic deformation and are unlikely to be affected by deterioration in strength caused by high-temperature heat generated in the course of generating electricity or by creep deformation. Also, since the spacer intervenes between the connector contact portion and the cell contact portion of the current-collecting member and prevents contact therebetween, there is no risk of the connector contact portion and the cell contact portion joining through sintering as a result of exposure to high-temperature heat generated in the course of generating electricity. Therefore, there can be prevented integration of the connector contact portion and the cell contact portion and associated instability of electrical connection.

Also, according to the fuel cell described in the claim, in addition to the above-mentioned effect, the following effect can be yielded. Specifically, since, as viewed in plane, the spacer is greater in size than the current-collecting member, there are unlikely to occur a reduction in the contact area between the interconnector and the current-collecting member and a reduction in the contact area between the electrode layer and the current-collecting member, which could otherwise to result from a positional shift of the spacer in the course of operation. Therefore, contact between the electrode layer of the single cell and the interconnector can be stably maintained.

Thus, the present invention can provide a fuel cell which, even in use over a long period of time, good electrical connection can be maintained.

According to the fuel cell described in the claim, since one of or both of the connector contact portion and the cell contact portion have a warp end formed at a side opposite the connection portion for engagement with an edge of the spacer, the spacer is stably disposed between the connector contact portion and the cell contact portion and is unlikely to be detached. Thus, since the current-collecting member and the spacer, which is attached to the current-collecting member, can be handled substantially as a unitary article, efficiency in production of fuel cells is effectively improved.

According to the fuel cell described in the claim, since one of or both of the connector contact portion and the cell contact portion have an inwardly-warped warp end formed at a side opposite the connection portion, the spacer is stably disposed between the connector contact portion and the cell contact portion and is unlikely to positionally shift in the course of operation.

According to the fuel cell described in the claim, since the warp end is engaged with an edge of the spacer, the current-collecting member and the spacer, which is attached to the current-collecting member, can be handled substantially as a unitary article. Therefore, efficiency in production of fuel cells is effectively improved.

Also, as described in the claim, the warp end is formed through shear deformation which occurs when at least one of the connector contact portion and the cell contact portion is stamped from a metal sheet. Therefore, the shear deformation which is a bother in itself in metal stamping can be effectively utilized. Therefore, there can be eliminated a step of machining or correcting a shear-deformed portion formed in metal stamping, and there can be eliminated an additional step of forming the warp end.

Also, according to the fuel cell described in the claim, since a contact region between the spacer and the cell contact portion, a contact region between the spacer and the connector contact portion, and a contact region between the opposite electrode layer and the current-collecting member corresponding to the opposite electrode layer are aligned with one another, contact pressure is efficiently applied to the contact regions while a harmful planar bending moment, which is a potential cause of breakage of the single cell, is hardly applied to the contact regions.

Also, according to the fuel cell described in the claim, since the spacer covers the entire contact region between the cell contact portion and the electrode layer, appropriate contact pressure can be applied to the entire contact region.

Also, by means of the spacer being formed of a material described in the claim, appropriate contact pressure can be continuously applied to the current-collecting members even in a high-temperature environment in the course of generating electricity.

According to the fuel cell described in the claim, the interconnectors, the single cell, and the current-collecting members are stacked and tightened together with the tightening member, whereby, with the spacer functioning as a core, the cell contact portion of the current-collecting member is reliably in contact with the electrode layer, and the connector contact portion of the current-collecting member is reliably in contact with the interconnector; therefore, electrical connection established by the current-collecting members is stabilized.

Also, according to the fuel cell described in the claim, the spacer is higher in thermal expansion coefficient than the tightening member; thus, even though the tightening member thermally expands through exposure to heat in the course of generating electricity, causing deterioration in tightening force of tightening together the interconnectors, the single cell, and the current-collecting members, since the spacer thermally expands more than do the tightening members, an action of pressing against the current-collecting members is maintained.

Also, by means of the current-collecting members being formed of a porous metal, a metal mesh, wire, or a punched metal as described in the claim, diffusivity of fuel gas and oxidizer gas is improved as compared with the case of the current-collecting members being formed of a simple plate material.

Also, in the case of the cell contact portion being joined to the surface of the electrode layer of the single cell as described in the claim, since the cell contact portion unitarily follows deformation of the single cell resulting from temperature cycles and fluctuations in fuel pressure and air pressure, stable electrical connection is established.

Also, by means of the connector contact portion of the current-collecting member being joined to the interconnector as described in the claim, even though the single cell is deformed as a result of temperature cycles and fluctuations in fuel pressure and air pressure, electrical connection can be stably maintained between the connector contact portion and the interconnector.

Also, by means of the current-collecting member being disposed between the anode layer and the interconnector and being formed of Ni or an Ni alloy as described in the claim, the cell contact portion and the connector contact portion of the current-collecting member can be joined to the anode layer and the interconnector, respectively, merely through application of heat after the fuel cell is assembled.

Specifically, in view of material properties, Ni or an Ni alloy is excellent in joining to the anode layer and to the interconnector; furthermore, the cell contact portion and the connector contact portion of the current-collecting member are reliably in contact with the single cell and the interconnector, respectively, by virtue of the spacer's pressing; thus, through application of heat after completion of assembly, the cell contact portion is diffusion-bonded to Ni contained in the anode layer of the single cell, and the connector contact portion is diffusion-bonded to the interconnector, whereby these members are integrated together. In this manner, when the cell contact portion and the connector contact portion are integrated with the single cell and the interconnector, respectively, through bonding, electrical connection is stabilized between the cell body and the interconnector.

Since the temperature of the fuel cell reaches around 700° C. to 1,000° C., the cell contact portion and the connector contact portion can be joined to the anode layer and the interconnector, respectively, with heat generated in the course of generating electricity. Therefore, a step of applying heat can be eliminated, whereby energy can be saved.

Also, since the fuel cell stack described in the claim is configured such that a plurality of the fuel cells according to any one of the aforementioned claims are stacked and fixed together by the tightening member, good electrical connection can be maintained in use over a long period of time.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 Perspective view of fuel cell apparatus.

FIG. 2 Perspective view of a fuel cell.

FIG. 3 Exploded perspective view of the fuel cell.

FIG. 4 Exploded perspective view of the fuel cell showing limited components thereof.

FIG. 5 Longitudinal sectional view showing the fuel cell with its laterally intermediate portion omitted.

FIG. 6 Longitudinal sectional view taken orthogonally to FIG. 5.

FIG. 7 Sectional view taken along line A-A of FIG. 5.

FIG. 8 Sectional view taken along line B-B of FIG. 5.

FIG. 9 Perspective view of current-collecting members.

FIG. 10( a) is a perspective view of a spacer, and FIG. 10( b) is a perspective view of a sheet of the current-collecting members to be assembled to the spacer.

FIG. 11 Perspective view showing a modified sheet of the current-collecting members of FIG. 10( b).

FIG. 12 Longitudinal sectional view of a fuel cell according to another embodiment with its laterally intermediate portion omitted.

FIG. 13 Longitudinal sectional view of a fuel cell according to a further embodiment.

MODES FOR CARRYING OUT THE INVENTION

At present, fuel cells are roughly classified into four types according to materials for electrolyte; specifically, a polymer electrolyte fuel cell (PEFC) which uses a polymer electrolyte membrane as electrolyte, a phosphoric-acid fuel cell (PAFC) which uses phosphoric acid as electrolyte, a molten carbonate fuel cell (MCFC) which uses Li—Na/K carbonate as electrolyte, and a solid oxide fuel cell (SOFC) which uses, for example, ZrO₂ ceramic as electrolyte. These types differ in working temperature (temperature at which ions can move through electrolyte); at present, working temperatures are as follows: room temperature to about 90° C. for PEFC, about 150° C. to 200° C. for PAFC, about 650° C. to 700° C. for MCFC, and about 700° C. to 1,000° C. for SOFC.

As shown in FIG. 1, a fuel cell apparatus 1 according to an embodiment of the present invention is an SOFC apparatus which uses, for example, ZrO₂ ceramic as an electrolyte layer 2. The fuel cell apparatus 1 includes fuel cells 3, each of which is a minimum unit for generating electricity; an air supply channel 4 for supplying air to the fuel cells 3; an air discharge channel 5 for discharging air from the apparatus; a fuel supply channel 6 for supplying fuel gas to the fuel cells 3; a fuel discharge channel 7 for discharging fuel gas from the apparatus; a fixing member 9 for fixing a stack of the fuel cells 3, or a group of cells, to thereby form a fuel cell stack 8; a container 10 which contains the fuel cell stack 8; and output members 11 for outputting electricity generated in the fuel cell stack 8.

[Fuel Cell]

The fuel cell 3 has a square shape as viewed in plane; as shown in the exploded perspective views of FIGS. 3 and 4, the fuel cell 3 is formed by stacking an upper (*herein, the terms “upper” and “lower” are based on illustration on drawings and used for convenience of description and do not necessarily mean absolute vertical upper and lower, and the same also applies in the following description) interconnector 12 formed of an electrically conductive square plate of ferritic stainless steel or the like; a lower interconnector 13 formed of an electrically conductive square plate of ferritic stainless steel or the like; a single cell 20 located at a substantially middle position between the upper and lower interconnectors 12 and 13 while being spaced from the interconnectors 12 and 13, and having an electrode layer (hereinafter, called the “cathode layer”) 14 formed on a surface of an electrolyte layer 2 opposite the inner surface (lower surface) of the upper interconnector 12 and the other electrode layer (hereinafter, called the “anode layer”) 15 formed on a surface of the electrolyte layer 2 opposite the inner surface (upper surface) of the lower interconnector 13; an air chamber 16 formed between the upper interconnector 12 and the cathode layer 14; a fuel chamber 17 formed between the lower interconnector 13 and the anode layer 15; current-collecting members 18 on the cathode layer 14 side disposed in the air chamber 16 and electrically connecting the cathode layer 14 and the upper interconnector 12; and current-collecting members 19 on the anode layer 15 side disposed in the fuel chamber 17 and electrically connecting the anode layer 15 and the lower interconnector 13; and the fuel cell 3 has tightening through holes 47 extending therethrough and formed at corners of the square shape and at middle positions of two opposite sides of the square shape for allowing tightening members 46 a to 46 f, which will be described later, of the fixing member 9 to be inserted through the tightening through holes 47.

[Electrolyte Layer]

In addition to ZrO₂ ceramic, materials used to form the electrolyte layer 2 include LaGaO₃ ceramic, BaCeO₃ ceramic, SrCeO₃ ceramic, SrZrO₃ ceramic, and CaZrO₃ ceramic.

[Anode Layer]

An example material for the anode layer 15 is a mixture of metal such as Ni or Fe and at least one of ceramics such as ZrO₂ ceramics, such as zirconia stabilized with at least one of rare earth elements such as Sc and Y, and CeO₂ ceramics. Also, material for the anode layer 15 may be metal such as Pt, Au, Ag, Pb, Ir, Ru, Rh, Ni, or Fe, and these metals may be used singly or in the form of an alloy of two or more of them. Furthermore, another example material for the anode layer 15 is a mixture (including cermet) of one or more of these metals and/or an alloy of these metals and at least one of the above-mentioned ceramics. A further example material for the anode layer 15 is a mixture of an oxide of metal such as Ni or Fe and at least one of the above-mentioned ceramics.

[Cathode Layer]

Example materials for the cathode layer 14 include various metals, oxides of metals, and complex oxides of metals. Examples of the metals include Pt, Au, Ag, Pb, Ir, Ru, and Rh, and alloys which contain two or more of the metals. Furthermore, examples of the oxides of metals include oxides of La, Sr, Ce, Co, Mn, and Fe (La₂O₃, SrO, Ce₂O₃, Co₂O₃, MnO₂, and FeO). Examples of the complex oxides of metals include complex oxides which contain at least La, Pr, Sm, Sr, Ba, Co, Fe, or Mn (La_(1-x)Sr_(x)CoO₃ complex oxide, La_(1-x)Sr_(x)FeO₃ complex oxide, La_(1-x)Sr_(x)Co_(1-y)FeO₃ complex oxide, La_(1-x)Sr_(x)MnO₃ complex oxide, Pr_(1-x)Ba_(x)CoO₃ complex oxide, and Sm_(1-x)Sr_(x)CoO₃ complex oxide).

[Fuel Chamber]

As shown in FIGS. 3 to 6, the fuel chamber 17 assumes the form of a square chamber defined by an anode gas channel forming insulating frame (hereinafter, may be called the “anode insulating frame”) 21 having the form of a picture frame and disposed on the upper surface of the lower interconnector 13 while surrounding the current-collecting members 19, and an anode frame 22 having the form of a picture frame and disposed on the upper surface of the anode insulating frame 21.

[Current-Collecting Members in Fuel Chamber]

As shown in FIG. 5, the current-collecting members 19 in the fuel chamber 17 are formed of, for example, Ni and are each configured such that there are integrally formed a connector contact portion 19 a in contact with the lower interconnector 13, a cell contact portion 19 b in contact with the anode layer 15 of the single cell 20, and a connection portion 19 c connecting the connector contact portion 19 a and the cell contact portion 19 b and bent by about 180 degrees to have a shape resembling the letter U. Also, as shown in FIG. 5, the cell contact portion 19 b of the current-collecting member 19 has an inwardly-warped warp end 19 e which is formed integrally at its end portion located opposite the connection portion 19 c and protrudes outward beyond the end of the spacer 58 for engagement with the end of the spacer 58.

The current-collecting members 19 of the embodiment are formed of, for example, a foil having a thickness of about 30 μm; accordingly, the connection portion 19 c can be bent and unbent in a direction intersecting with a plane, and is very small in elastically repulsive force against bending and unbending.

The current-collecting members 19 may be formed of, for example, a porous metal of Ni, a metal mesh of Ni, wire of Ni, or a punched metal of Ni, in addition to the above-mentioned method of formation. Also, the current-collecting members 19 in the fuel chamber 17 may be formed of metal resistant to oxidation, such as an Ni alloy or stainless steel, in addition to Ni.

The current-collecting members 19 are provided in a quantity of about several tens to one hundred (of course, depending on the size of the fuel chamber); the current-collecting members 19 may be individually arrayed on and welded (e.g., laser-welded or resistance-welded) to the interconnector 13; preferably, as shown in FIG. 10( b), the aforementioned foil is formed into a square flat sheet 190 compatible with the fuel chamber 17; cuts 19 d corresponding to the cell contact portions 19 b and the connection portions 19 c are made in the flat sheet 190; then, as shown in the enlarged view in FIG. 9, the connection portions 19 c are bent into a shape resembling the letter U such that the cell contact portions 19 b face the corresponding connector contact portions 19 a from above with a gap t (see the enlarged view in FIG. 5) therebetween. Thus, the flat sheet 190 having holes formed as a result of the cell contact portions 19 b being raised and bent is an aggregate of the connector contact portions 19 a; in the embodiment, the connector contact portions 19 a of the flat sheet 190 are joined to the lower interconnector 13 through laser welding or resistance welding.

In the above case, welding is employed as a joining method; however, the present invention is not limited thereto. Heat generated as a result of operation of the fuel cell apparatus may be utilized for joining the connector contact portions 19 a to the lower interconnector 13.

As shown in FIG. 11, the cuts 19 d for the current-collecting members 19 may be made in such a manner that the cell contact portions 19 b and the connection portions 19 c are integrated in row units. This allows the cell contact portions 19 b and the connection portions 19 c to be efficiently formed.

[Spacer]

As shown in FIG. 5, the spacer 58 is incorporated in the current-collecting members 19. The spacer 58 is disposed between the connector contact portions 19 a and the cell contact portions 19 b in such a manner as to separate the connector contact portions 19 a from the cell contact portions 19 b in the fuel chamber 17 located between the single cell 20 and the lower interconnector 13; in order for the spacer 58 to elastically press the cell contact portions 19 b and the connector contact portions 19 a in their contact directions; i.e., to elastically press the cell contact portions 19 b toward the single cell 20, and the connector contact portions 19 a toward the interconnector 13, by means of thermal expansion of the spacer 58 in its thickness direction at least in a working temperature range of the fuel cell apparatus, the thickness and material of the spacer 58 are determined such that, at a working temperature of the fuel cell apparatus of 700° C. to 1,000° C., thermal expansion of the spacer 58 is greater than that of the gap t.

The thickness of the spacer 58 may be determined so as to be, in a working temperature range of the fuel cell apparatus, greater than the gap t between the cell contact portions 19 b and the connector contact portion 19 a, but is preferably substantially equal to or slightly greater than at least the gap t between the cell contact portions 19 b and the connector contact portions 19 a at room temperature in an inactive condition of the fuel cell apparatus. Employment of such a thickness enables the spacer 58 to provide stable electrical contact between the connector contact portions 19 a and the interconnector 13 and between the cell contact portions 19 b and the single cell 20 even until the working temperature range is reached from start of generation of electricity.

Material of the spacer 58 is more flexible in the thickness direction than the current-collecting members 19, and the spacer 58 expands and contracts in response to fluctuations in the gap of the fuel chamber 17 caused by temperature cycles and variations of fuel pressure and air pressure. Specifically, in response to contraction of the gap of the fuel chamber 17, the spacer 58 contracts in the thickness direction to exhibit a cushioning action, thereby preventing cracking of the single cell 20, whereas, in response to expansion of the gap, the spacer 58 stabilizes electrical contact through resilience in the thickness direction.

Also, as shown in FIG. 5, the spacer 58 has such a length that one end thereof is located at a substantially deepest position in the connection portion 19 c of the current-collecting member 19, and the other end thereof recedes from an end of the cell contact portion 19 b located opposite the connection portion 19 c; thus, the warp end 19 e of the cell contact portion 19 b is engaged with the edge of the end of the spacer 58, whereby the spacer 58 is unlikely to positionally shift in relation to the current-collecting members 19.

In the embodiment, the entire region (length) of the spacer 58 as viewed in plane is contained in the region where, as viewed in plane, the cell contact portion 19 b and the anode layer 15 are in contact with each other (a region which extends from near the boundary between the cell contact portion 19 b and the connection portion 19 c to the warp end of the cell contact portion 19 b and in which the cell contact portion 19 b and the anode layer 15 are actually in contact with each other). Thus, an action of the spacer 58 is uniformly applied to the above-mentioned region of the cell contact portion 19 b.

Meanwhile, as shown in FIG. 5, the end of the spacer 58 located opposite the connection portion 19 c of the current-collecting member 19 also recedes from the corresponding end of the connector contact portion 19 a. Thus, an action of the spacer 58 is uniformly applied to the connector contact portion 19 a through the entire surface of the spacer 58.

The spacer 58 is formed of a material which is not sintered to the current-collecting member 19 in the working temperature range of the fuel cell apparatus; therefore, the cell contact portion 19 b and the connector contact portion 19 a are unlikely to be sintered to each other through direct contact. Also, the cell contact portion 19 b and the connector contact portion 19 a are unlikely to be sintered to each other through the spacer 58.

As a material for the spacer 58 which satisfies the above conditions, there may be used singly or in combination mica, alumina felt, vermiculite, carbon fiber, silicon carbide fiber, and silica. Through impartation of, for example, a sheet-like laminate structure as in the case of mica to these materials, the materials exhibit appropriate elasticity in response to load applied in the direction of lamination. The thermal expansion coefficient in the thickness direction (direction of lamination) of the spacer 58 formed of these materials is higher than the thermal expansion coefficient in the axial direction of the tightening members 46 a to 46 f, which will be described later.

The current-collecting members 19 of the embodiment are integrated into a unitary structure implemented through the flat sheet 190, which is an aggregate of the connector contact portions 19 a as mentioned above; as shown in FIG. 10(a), in order for the spacer 58 to be compatible with the structure, the spacer 58 is formed into a horizontal grating form such that, from a single rectangular material sheet which has substantially the same width as that of the flat sheet 190 and is slightly shorter than the flat sheet 190 (specifically, shorter by the total length of the cell contact portion 19 b and the connection portion 19 c), portions of the material sheet each corresponding to the cell contact portions 19 b and the connection portions 19 c arrayed in a row are cut out.

Then, the spacer 58 is placed on the flat sheet 190 which is shown in FIG. 10( b) and is to be formed into the current-collecting members 19; in this condition, as shown in the enlarged view of FIG. 9, the connection portions 19 c are bent by about 180 degrees into a shape resembling the letter U, and the warp ends 19 e are formed through bending, thereby forming the current-collecting members 19 with the spacer 58 incorporated therein such that the spacer 58 is unlikely to positionally shift. However, in the case where a plurality of the current-collecting members 19 are formed of a single flat sheet 190, the warp ends 19 e may be locally formed, for example, such that the current-collecting members 19 corresponding to at least four corners of the flat sheet 190 have the respective warp ends 19 e. In this case, positional shifts of the remaining current-collecting members 19 connected through the flat sheet 190 can be prevented. Also, the current-collecting members 19 not having the respective warp ends 19 e can increase the contact region between the spacer 58 and the cell contact portion 19 b through utilization of a portion corresponding to the warp end 19 e as a portion of the contact region, whereby preference is given to securement of electrical contact.

Incidentally, in the enlarged view of FIG. 9, the cell contact portions 19 b are formed through bending performed sequentially in the rightward direction from the cell contact portion 19 b located at the left corner position; however, this illustration is intended primarily to explain a working procedure; thus, the cell contact portions 19 b may be formed in unison through bending or may be formed sequentially from the cell contact portion 19 b located at a position convenient for working.

[Air Chamber]

As shown in FIGS. 3 to 6, the air chamber 16 assumes the form of a square chamber defined by an electrically conductive, thin metal separator 23 having the form of a square picture frame and having the electrolyte layer 2 affixed to the lower surface thereof, and a cathode gas channel forming insulating frame (hereinafter, may be called the “cathode insulating frame”) 24 having the form of a picture frame and disposed between the separator 23 and the upper interconnector 12 while surrounding the current-collecting members 18.

[Current-Collecting Members in Air Chamber]

The current-collecting members 18 in the air chamber 16 are dense electrically conductive members each having the form of a slender square bar and formed of, for example, stainless steel and are disposed in parallel with one another at fixed intervals while being in contact with the cathode layer 14 on the upper surface of the electrolyte layer 2 and the lower surface (inner surface) of the upper interconnector 12.

As shown in FIG. 5, as viewed in plane, at least portions of the current-collecting members 18 in the air chamber 16 are in contact with the cathode layer 14 in a region where the spacer 58 is in contact with the cell contact portions 19 b and with the connector contact portions 19 a. Thus, contact regions between the spacer 58 and the cell contact portions 19 b, contact regions between the spacer 58 and the connector contact portions 19 a, and contact regions between the cathode layer 14 and the current-collecting members 18 are aligned with one another; therefore, contact pressure can be efficiently applied to the contact regions while a harmful planar bending moment, which is a potential cause of breakage of the single cell 20, is hardly applied to the contact regions.

As described above, the fuel cell 3 forms the fuel chamber 17 and the air chamber 16 through cooperation with the lower interconnector 13, the anode insulating frame 21, the anode frame 22, the separator 23, the cathode insulating frame 24, and the upper interconnector 12. Also, the electrolyte layer 2 partitions the fuel cell 3 into the fuel chamber 17 and the air chamber 16 independently of each other, and the anode insulating frame 21 and the cathode insulating frame 24 electrically insulate the anode layer 15 side and the cathode layer 14 side from each other.

Also, the fuel cell 3 includes an air supply section 25 including the air supply channel 4 for supplying air into the air chamber 16, an air discharge section 26 including the air discharge channel 5 for discharging air from the air chamber 16 to an external system, a fuel supply section 27 including the fuel supply channel 6 for supplying fuel gas into the fuel chamber 17, and a fuel discharge section 28 including the fuel discharge channel 7 for discharging fuel gas from the fuel chamber 17 to an external system.

[Air Supply Section]

As shown in FIG. 7, the air supply section 25 includes an air supply through hole 29 extending in the vertical direction at a position located toward a corner and one side of the square fuel cell apparatus 1, an elongated-hole-like air supply manifold 30 formed in the cathode insulating frame 24 and communicating with the air supply through hole 29, a plurality of air supply communication channels 32 formed at equal intervals on the upper surface of a partition wall 31 which separates the air supply manifold 30 and the air chamber 16 from each other, by sinking corresponding portions of the upper surface, and the air supply channel 4 inserted through the air supply through hole 29 and adapted to supply air to the air supply manifold 30 from an external system.

[Air Discharge Section]

The air discharge section 26 includes an air discharge through hole 33 extending in the vertical direction at a position located toward a corner and one side opposite the air supply section 25 of the fuel cell apparatus 1, an elongated-hole-like air discharge manifold 34 formed in the cathode insulating frame 24 and communicating with the air discharge through hole 33, a plurality of air discharge communication channels 36 formed at equal intervals on the upper surface of a partition wall 35 which separates the air discharge manifold 34 and the air chamber 16 from each other, by sinking corresponding portions of the upper surface, and the tubular air discharge channel 5 inserted through the air discharge through hole 33 and adapted to discharge air from the air discharge manifold 34 to an external system.

[Fuel Supply Section]

As shown in FIG. 8, the fuel supply section 27 includes a fuel supply through hole 37 extending in the vertical direction at a position located toward a corner opposite the air supply through hole 29 and the same one side as that of the air supply section 25 of the square fuel cell apparatus 1, an elongated-hole-like fuel supply manifold 38 formed in the anode insulating frame 21 and communicating with the fuel supply through hole 37, a plurality of fuel supply communication channels 40 formed at equal intervals on the upper surface of a partition wall 39 which separates the fuel supply manifold 38 and the fuel chamber 17 from each other, by sinking corresponding portions of the upper surface, and the tubular fuel supply channel 6 inserted through the fuel supply through hole 37 and adapted to supply fuel to the fuel supply manifold 38 from an external system.

[Fuel Discharge Section]

The fuel discharge section 28 includes a fuel discharge through hole 41 extending in the vertical direction at a position located toward a corner and one side opposite the fuel supply section 27 of the fuel cell apparatus 1, an elongated-hole-like fuel discharge manifold 42 formed in the anode insulating frame 21 and communicating with the fuel discharge through hole 41, a plurality of fuel discharge communication channels 44 formed at equal intervals on the upper surface of a partition wall 43 which separates the fuel discharge manifold 42 and the fuel chamber 17 from each other, by sinking corresponding portions of the upper surface, and the tubular fuel discharge channel 7 inserted through the fuel discharge through hole 41 and adapted to discharge fuel gas from the fuel discharge manifold 42 to an external system.

[Fuel Cell Stack]

As shown in FIG. 1, the fuel cell stack 8 is configured such that a plurality of the fuel cells 3 are stacked into a group of cells, and the group of cells is fixed with the fixing member 9. In the case of stacking a plurality of the fuel cells 3, two adjacent fuel cells 3 share one interconnector which serves as the upper interconnector 12 of the lower fuel cell 3 and as the lower interconnector 13 of the upper fuel cell 3.

The fixing member 9 is a set consisting of a pair of end plates 45 a and 45 b for vertically clamping the fuel cell stack 8, and six sets of tightening members 46 a to 46 f for clamping the end plates 45 a and 45 b and the fuel cell stack 8 by fixing bolts, with nuts, inserted through tightening holes (not shown) of the end plates 45 a and 45 b and through the tightening through holes 47 of the fuel cell stack 8. Material for the tightening members 46 a to 46 f is, for example, INCONEL 601.

The air supply channel 4 is mounted to the fuel cell stack 8 of the fuel cell apparatus 1 in such a manner as to vertically extend through the through holes (not shown) of the end plates 45 a and 45 b and through the air supply through hole 29. An end of the tubular channel is closed, and, as shown in FIG. 7, the tubular channel has horizontal holes 48 corresponding to the air supply manifolds 30, whereby air is supplied to the air supply manifolds 30 through the horizontal holes 48.

Similarly, the air discharge channel 5 receives air discharged from the air discharge manifolds 34 through corresponding horizontal holes 49 thereof and discharges air to an external system; as shown in FIG. 8, the fuel supply channel 6 supplies fuel gas to the fuel supply manifolds 38 through corresponding horizontal holes 50 thereof; and the fuel discharge channel 7 receives fuel gas discharged from the fuel discharge manifolds 42 through corresponding horizontal holes 51 thereof and discharges fuel gas to an external system.

[Container]

The container 10 for containing the fuel cell stack 8 is a heat-resistant closed structure and is, as shown in FIG. 1, configured such that two half containers 53 a and 53 b having flanges 52 a and 52 b, respectively, at their opening portions, face each other and are joined together. The bolts of the tightening members 46 a to 46 f protrude from the top of the container 10, and nuts 54 are threadingly engaged with protruding portions of the tightening members 46 a to 46 f, respectively, thereby fixing the fuel cell stack 8 within the container 10. Also, the air supply channel 4, the air discharge channel 5, the fuel supply channel 6, and the fuel discharge channel 7 protrude from the top of the container 10, and, to protruding portions thereof, air and fuel gas supply sources, etc., are connected.

[Output Members]

The output members 11 for outputting electricity generated in the fuel cell apparatus 1 are the tightening members 46 a to 46 d located at corners of the fuel cell stack 8, and the end plates 45 a and 45 b. Specifically, a pair of the tightening members 46 a and 46 c located diagonally are electrically connected to the upper end plate 45 a, which functions as a positive pole, and the other pair of the tightening members 46 b and 46 d are electrically connected to the lower end plate 45 b, which functions as a negative pole. Of course, the tightening members 46 a and 46 d connected to a positive pole and the tightening members 46 b and 46 c connected to a negative pole are electrically insulated from the end plates 45 b and 45 a, respectively, of opposite polarities by means of intervention of the insulating washer 55 (see FIG. 1), and from the fuel cell stack 8 by means of provision of gaps in relation to walls of the tightening through holes 47. Thus, the tightening members 46 a and 46 c of the fixing member 9 function as output terminals of positive polarity connected to the upper end plate 45 a, and the other tightening members 46 b and 46 d function as output terminals of negative polarity connected to the lower end plate 45 b.

[Generation of Electricity]

Air supplied to the air supply channel 4 of the fuel cell apparatus 1 flows downward in FIG. 7; specifically, is supplied into the air chamber 16 through the air supply section 25 composed of the upper air supply channel 4, the air supply manifold 30, and the air supply communication channels 32; passes through gas flow channels 56 formed between the current-collecting members 18 in the air chamber 16; and is then discharged to an external system through the air discharge section 26 composed of air discharge communication channels 36, the air discharge manifold 34, and the air discharge channel 5.

At the same time, fuel gas; for example, hydrogen, supplied to the fuel supply channel 6 of the fuel cell apparatus 1 flows downward in FIG. 8; specifically, is supplied into the fuel chamber 17 through the fuel supply section 27 composed of the upper fuel supply channel 6, the fuel supply manifold 38, and the fuel supply communication channels 40; diffuses and passes through gas flow channels 57 of the current-collecting members 19 in the fuel chamber 17; and is then discharged to an external system through the fuel discharge section 28 composed of the fuel discharge communication channels 44, the fuel discharge manifold 42, and the fuel discharge channel 7.

While air and fuel gas are being supplied and discharged as mentioned above, the temperature in the container 10 is increased to 700° C. to 1,000° C., whereby air and fuel gas react with each other through the cathode 14, the electrolyte layer 2, and the anode 15; thus, electric energy of direct current is generated with the cathode 14 functioning as a positive pole and the anode 15 functioning as a negative pole. Since the principle of generation of electric energy in the fuel cell 3 is well known, repeated description thereof is omitted.

As mentioned above, the cathode 14 is electrically connected to the upper connector 12 through the current-collecting members 18, whereas the anode 15 is electrically connected to the lower connector 13 through the current-collecting members 19; since the fuel cell stack 8 is such that a plurality of the fuel cells 3 are stacked and connected in series, the upper end plate 45 a functions as a positive pole, whereas the lower end plate 45 b functions as a negative pole; and electric energy can be output from the fuel cell apparatus through the tightening members 46 a to 46 d, which also function as output terminals.

The above-mentioned fuel cell apparatus repeats a temperature cycle such that temperature increases in the course of generating electricity and decreases as a result of suspension of generation of electricity. Therefore, all members which constitute the fuel chamber 17 and the air chamber 16, and the tightening members 46 a to 46 f repeat thermal expansion and contraction; accordingly, the gaps of the fuel chamber 17 and the air chamber 16 repeat expansion and contraction.

Also, fuel pressure and air pressure may fluctuate, and, as a result of fluctuations in the pressures, the single cell 20 is deformed, whereby the gaps of the fuel chamber 17 and the air chamber 16 expand or contract.

In response to such variations in the expanding direction of the fuel chamber 17 and the air chamber 16, in the embodiment, the current-collecting members 19 in the fuel chamber 17 press the single cell 20 primarily by thermal expansion of the spacer 58 in the same direction as that of elasticity of the spacer 58 in the stacking direction (the thickness direction or the tightening direction of the tightening members 46 a to 46 f), whereby electrical contact is stably maintained. Since pressing of the current-collecting members 19 against the single cell 20 is transmitted to the air chamber 16 side, electrical contact in the air chamber 16 is also stably maintained.

Also, in response to variations in the contracting direction of the fuel chamber 17 and the air chamber 16, stress applied to the single cell 20 is mitigated primarily by contraction of the spacer 58 in the fuel chamber 17.

Also, when the current-collecting members 19 on the anode layer 15 side are formed of Ni or an Ni alloy, in a high-temperature environment in the course of generating electricity, the cell contact portions 19 b are diffusion-bonded to Ni contained in the anode layer 15, thereby being integrated with the anode layer 15. Therefore, electrical connection through the current-collecting members 19 is more stably maintained.

Preferably, NiO paste is applied to the anode layer 15 to form a joining layer. Through formation of such a joining layer, as a result of flow of electric current in H₂, NiO becomes Ni, whereby the performance of joining between the current-collecting members 19 and the anode layer 15 is further improved. The joining layer may be formed through application of Pt paste to the anode layer 15.

In the embodiment, the flat sheet 190, which is an aggregate of the connector contact portions 19 a, is welded to the lower interconnector 13; however, the interconnector 13 and the current-collecting members 19 can be joined together in a high-temperature environment in the course of generating electricity, through combination of materials for the lower interconnector 13 and the flat sheet 190 such that the materials can be diffusion-bonded to each other in the high-temperature environment in the course of generating electricity (e.g., combination of Crofer22H and Ni) or through formation of such a joining layer mentioned above on the inner surface of the lower interconnector 13.

The present invention has been described with reference to the embodiment; however, the present invention is not limited thereto. For example, in the embodiment, the current-collecting members 18 in the air chamber 16 and the current-collecting members 19 in the fuel chamber 17 differ in configuration; however, the current-collecting members in the air chamber 16 and the current-collecting members 19 in the fuel chamber 17 may have the same configuration.

Also, the orientation of the current-collecting members 19 in the fuel chamber 17 is not limited to that shown in FIG. 5; for example, the current-collecting members 19 may be inverted upside-down as shown in FIG. 12. In such a case, the flat sheet 190 is an aggregate of the cell contact portions 19 b. The warp ends 19 e are formed at the connector contact portions 19 a, respectively.

Also, the embodiment refers separately to an example of providing the cell contact portions 19 b with the respective warp ends 19 e as shown in FIG. 5 and to an example of providing the connector contact portions 19 a with the respective warp ends 19 e as shown in FIG. 12; however, as shown in FIG. 13, the cell contact portions 19 b and the connector contact portions 19 a may be provided with the respective warp ends 19 e.

Also, in the embodiment, end portions of the cell contact portions 19 b or the connector contact portions 19 a are bent to form the warp ends 19 e; however, shear-deformed portions formed in stamping the cell contact portions 19 b or the connector contact portions 19 a from a metal sheet may be left intact and used as the warp ends 19 e.

Also, in the embodiment, the electrolyte layer 2 assumes the form of a flat plate; however, the electrolyte layer 2 may assume the form of, for example, a cylinder or a flat cylinder.

DESCRIPTION OF REFERENCE NUMERALS

-   1: fuel cell apparatus -   2: electrolyte layer -   3: fuel cell -   8: fuel cell stack -   12, 13: interconnector -   14: cathode layer -   15: anode layer -   18, 19: current-collecting members -   19 a: connector contact portion -   19 b: cell contact portion -   19 c: connection portion -   19 e: warp end -   20: single cell -   46 a to 46 f: tightening member -   58: spacer 

1-13. (canceled)
 14. A fuel cell comprising: a pair of interconnectors; a single cell located between the interconnectors and having a plate-like electrolyte layer and electrode layers formed on upper and lower surfaces, respectively, of the electrolyte layer; and current-collecting members disposed between the electrode layers and the interconnectors, respectively, and adapted to electrically connect the corresponding electrode layers and interconnectors; the fuel cell being characterized in that the current-collecting member corresponding to at least one of the electrode layers comprises a connector contact portion in contact with the interconnector, a cell contact portion in contact with the electrode layer of the single cell, a connection portion connecting the connector contact portion and the cell contact portion, and a spacer disposed between the connector contact portion and the cell contact portion; and an end of the spacer located opposite the connection portion recedes from an end of the cell contact portion located opposite the connection portion and from an end of the connector contact portion located opposite the connection portion.
 15. A fuel cell according to claim 14, wherein one of or both of the connector contact portion and the cell contact portion have a warp end formed at a side opposite the connection portion for engagement with an edge of the spacer.
 16. A fuel cell according to claim 15, wherein the warp end is formed through shear deformation which occurs when at least one of the connector contact portion and the cell contact portion is stamped from a metal sheet.
 17. A fuel cell according to claim 14, wherein, as viewed in plane, at least a portion of the current-collecting member opposite the current-collecting member corresponding to the one electrode layer is in contact with the other electrode layer in a region where the spacer is in contact with the cell contact portion and with the connector contact portion.
 18. A fuel cell according to claim 14, wherein the entire region of the spacer as viewed in plane is contained, as viewed in plane, in a region of contact between the cell contact portion and the electrode layer.
 19. A fuel cell according to claim 14, wherein the spacer is of at least one of mica, alumina felt, vermiculite, carbon fiber, silicon carbide fiber, and silica.
 20. A fuel cell according to claim 14, further comprising a tightening member for unitarily tightening a stack of the interconnectors, the single cell, and the current-collecting members, wherein the tightening member and the spacer press the cell contact portion of the current-collecting member against the single cell and the connector contact portion of the current-collecting member against the interconnector.
 21. A fuel cell according to claim 20, wherein the spacer is higher in thermal expansion coefficient in a tightening direction than the tightening member.
 22. A fuel cell according to claim 14, wherein the current-collecting members are formed of a porous metal, a metal mesh, wire, or a punched metal.
 23. A fuel cell according to claim 1, wherein the cell contact portion of the current-collecting member is joined to a surface of the electrode layer of the single cell.
 24. A fuel cell according to claim 14, wherein the connector contact portion of the current-collecting member is joined to the interconnector.
 25. A fuel cell according to claim 14, wherein the current-collecting member is disposed between the electrode layer corresponding to fuel gas and the interconnector and is formed of Ni or an Ni alloy.
 26. A fuel cell stack characterized in that a plurality of the fuel cells according to claim 14 are stacked and fixed together by the tightening member.
 27. A fuel cell according to claim 14, wherein the electrolyte layer assumes a plate-like form.
 28. A fuel cell according to claim 15, wherein the warp end is engaged with an edge of the spacer. 